SSPT: Shallowest Shortest Path Tree: (Short Paper)

Omer Asher; Shlomi Dolev; Li On Raviv

doi:10.1007/978-3-032-10759-6_25

SSPT: Shallowest Shortest Path Tree: (Short Paper)

Omer Asher
, Shlomi Dolev
, Li On Raviv

Ben-Gurion University of the Negev
Gilat Networks

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

This paper introduces a polynomial-time modification to Dijkstra’s algorithm aimed at constructing a Shallowest Shortest Path Tree (SSPT) from a source vertex s in a weighted graph. Unlike the standard Dijkstra’s algorithm, which prioritizes minimizing path weights without regard for path depths (i.e., the number of edges), this modified approach ensures that among paths of equal weight, the one with the fewest edges is selected. This enhancement is achieved by tracking both path weight and depth during the algorithm’s execution. The paper provides formal definitions of key concepts and proves the correctness of the modified algorithm. This work extends the applicability of shortest path algorithms to scenarios where minimizing path depths is also substantial. A formal treatment and proof for the solution are presented. We apply the SSPT to approximate solutions for the Directed Steiner Tree Problem on several graphs, including Erdős-Rényi random graphs with randomly and uniformly selected terminals. In particular, we show that using this tree allows us to notably reduce the number of nonterminal nodes included in the solution. We believe that further development of this method may lead to improved approximation strategies for Steiner-type problems and related optimization tasks.

Original language	English
Title of host publication	Cyber Security, Cryptology, and Machine Learning - 9th International Symposium, CSCML 2025, Proceedings
Editors	Adi Akavia, Shlomi Dolev, Anna Lysyanskaya, Rami Puzis
Publisher	Springer Science and Business Media Deutschland GmbH
Pages	358-371
Number of pages	14
ISBN (Print)	9783032107589
DOIs	https://doi.org/10.1007/978-3-032-10759-6_25
State	Published - 2026
Externally published	Yes
Event	9th International Symposium on Cyber Security, Cryptology, and Machine Learning, CSCML 2025 - Be'er Sheva, Israel Duration: 4 Dec 2025 → 5 Dec 2025

Publication series

Name	Lecture Notes in Computer Science
Volume	16244 LNCS
ISSN (Print)	0302-9743
ISSN (Electronic)	1611-3349

Conference

Conference	9th International Symposium on Cyber Security, Cryptology, and Machine Learning, CSCML 2025
Country/Territory	Israel
City	Be'er Sheva
Period	4/12/25 → 5/12/25

Bibliographical note

Publisher Copyright:
© The Author(s), under exclusive license to Springer Nature Switzerland AG 2026.

Access to Document

10.1007/978-3-032-10759-6_25

Cite this

Asher, O., Dolev, S., & Raviv, L. O. (2026). SSPT: Shallowest Shortest Path Tree: (Short Paper). In A. Akavia, S. Dolev, A. Lysyanskaya, & R. Puzis (Eds.), Cyber Security, Cryptology, and Machine Learning - 9th International Symposium, CSCML 2025, Proceedings (pp. 358-371). (Lecture Notes in Computer Science; Vol. 16244 LNCS). Springer Science and Business Media Deutschland GmbH. https://doi.org/10.1007/978-3-032-10759-6_25

Asher, Omer ; Dolev, Shlomi ; Raviv, Li On. / SSPT : Shallowest Shortest Path Tree: (Short Paper). Cyber Security, Cryptology, and Machine Learning - 9th International Symposium, CSCML 2025, Proceedings. editor / Adi Akavia ; Shlomi Dolev ; Anna Lysyanskaya ; Rami Puzis. Springer Science and Business Media Deutschland GmbH, 2026. pp. 358-371 (Lecture Notes in Computer Science).

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abstract = "This paper introduces a polynomial-time modification to Dijkstra{\textquoteright}s algorithm aimed at constructing a Shallowest Shortest Path Tree (SSPT) from a source vertex s in a weighted graph. Unlike the standard Dijkstra{\textquoteright}s algorithm, which prioritizes minimizing path weights without regard for path depths (i.e., the number of edges), this modified approach ensures that among paths of equal weight, the one with the fewest edges is selected. This enhancement is achieved by tracking both path weight and depth during the algorithm{\textquoteright}s execution. The paper provides formal definitions of key concepts and proves the correctness of the modified algorithm. This work extends the applicability of shortest path algorithms to scenarios where minimizing path depths is also substantial. A formal treatment and proof for the solution are presented. We apply the SSPT to approximate solutions for the Directed Steiner Tree Problem on several graphs, including Erd{\H o}s-R{\'e}nyi random graphs with randomly and uniformly selected terminals. In particular, we show that using this tree allows us to notably reduce the number of nonterminal nodes included in the solution. We believe that further development of this method may lead to improved approximation strategies for Steiner-type problems and related optimization tasks.",

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Asher, O, Dolev, S & Raviv, LO 2026, SSPT: Shallowest Shortest Path Tree: (Short Paper). in A Akavia, S Dolev, A Lysyanskaya & R Puzis (eds), Cyber Security, Cryptology, and Machine Learning - 9th International Symposium, CSCML 2025, Proceedings. Lecture Notes in Computer Science, vol. 16244 LNCS, Springer Science and Business Media Deutschland GmbH, pp. 358-371, 9th International Symposium on Cyber Security, Cryptology, and Machine Learning, CSCML 2025, Be'er Sheva, Israel, 4/12/25. https://doi.org/10.1007/978-3-032-10759-6_25

SSPT: Shallowest Shortest Path Tree: (Short Paper). / Asher, Omer; Dolev, Shlomi; Raviv, Li On.
Cyber Security, Cryptology, and Machine Learning - 9th International Symposium, CSCML 2025, Proceedings. ed. / Adi Akavia; Shlomi Dolev; Anna Lysyanskaya; Rami Puzis. Springer Science and Business Media Deutschland GmbH, 2026. p. 358-371 (Lecture Notes in Computer Science; Vol. 16244 LNCS).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Asher, Omer

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N1 - Publisher Copyright: © The Author(s), under exclusive license to Springer Nature Switzerland AG 2026.

PY - 2026

Y1 - 2026

N2 - This paper introduces a polynomial-time modification to Dijkstra’s algorithm aimed at constructing a Shallowest Shortest Path Tree (SSPT) from a source vertex s in a weighted graph. Unlike the standard Dijkstra’s algorithm, which prioritizes minimizing path weights without regard for path depths (i.e., the number of edges), this modified approach ensures that among paths of equal weight, the one with the fewest edges is selected. This enhancement is achieved by tracking both path weight and depth during the algorithm’s execution. The paper provides formal definitions of key concepts and proves the correctness of the modified algorithm. This work extends the applicability of shortest path algorithms to scenarios where minimizing path depths is also substantial. A formal treatment and proof for the solution are presented. We apply the SSPT to approximate solutions for the Directed Steiner Tree Problem on several graphs, including Erdős-Rényi random graphs with randomly and uniformly selected terminals. In particular, we show that using this tree allows us to notably reduce the number of nonterminal nodes included in the solution. We believe that further development of this method may lead to improved approximation strategies for Steiner-type problems and related optimization tasks.

AB - This paper introduces a polynomial-time modification to Dijkstra’s algorithm aimed at constructing a Shallowest Shortest Path Tree (SSPT) from a source vertex s in a weighted graph. Unlike the standard Dijkstra’s algorithm, which prioritizes minimizing path weights without regard for path depths (i.e., the number of edges), this modified approach ensures that among paths of equal weight, the one with the fewest edges is selected. This enhancement is achieved by tracking both path weight and depth during the algorithm’s execution. The paper provides formal definitions of key concepts and proves the correctness of the modified algorithm. This work extends the applicability of shortest path algorithms to scenarios where minimizing path depths is also substantial. A formal treatment and proof for the solution are presented. We apply the SSPT to approximate solutions for the Directed Steiner Tree Problem on several graphs, including Erdős-Rényi random graphs with randomly and uniformly selected terminals. In particular, we show that using this tree allows us to notably reduce the number of nonterminal nodes included in the solution. We believe that further development of this method may lead to improved approximation strategies for Steiner-type problems and related optimization tasks.

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Asher O, Dolev S, Raviv LO. SSPT: Shallowest Shortest Path Tree: (Short Paper). In Akavia A, Dolev S, Lysyanskaya A, Puzis R, editors, Cyber Security, Cryptology, and Machine Learning - 9th International Symposium, CSCML 2025, Proceedings. Springer Science and Business Media Deutschland GmbH. 2026. p. 358-371. (Lecture Notes in Computer Science). doi: 10.1007/978-3-032-10759-6_25

SSPT: Shallowest Shortest Path Tree: (Short Paper)

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